Prediction of fracture healing under axial loading, shear loading and bending is possible using distortional and dilatational strains as determining mechanical stimuli

Steiner, Malte; Claes, Lutz; Ignatius, Anita; Niemeyer, Frank; Simon, Ulrich; Wehner, Tim

doi:10.1098/rsif.2013.0389

Cited by 47 publications

(37 citation statements)

References 57 publications

(141 reference statements)

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“…The finding that lower tensile strains are associated with bone formation over formation of any soft tissue is not consistent with the theory of Carter and colleagues (Carter et al 1998). The present data are also not consistent with studies (Shefelbine et al 2005; Steiner et al 2013) that have implemented the theory of Claes and Heigele (Claes et al 1997; Claes and Heigele 1999) to posit that cartilage formation is favored only in regions of large values of hydrostatic pressure (which may correspond loosely to negative values of dilatation) and is not dependent on the octahedral shear strain. Some of these and other prior studies using numerical simulation of skeletal repair have incorporated physiochemical and/or biological factors such as hypoxia and angiogenesis (Burke et al 2013; Simon et al 2011).…”

Section: Discussioncontrasting

confidence: 99%

“…These features include shear strain and interstitial fluid flow (Lacroix and Prendergast 2002; Prendergast et al 1997), strain and hydrostatic pressure (Claes et al 1997; Claes and Heigele 1999), shear strain only (Gomez-Benito et al 2005), and tensile strain and hydrostatic pressure (Carter et al 1998). Tests of these theories, largely using numerical simulation to estimate the mechanical microenvironment and then to predict the healing outcome, have produced somewhat contradictory results (Isaksson et al 2006; Steiner et al 2013). Experimental evidence obtained by using digital image correlation to measure the strain microenvironment has pointed to the importance of shear strain (as represented by the octahedral shear strain) and, to a lesser extent, tensile strain (as represented by the maximum principal strain) (Morgan et al 2010).…”

Section: Introductionmentioning

confidence: 99%

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Mechanical microenvironments and protein expression associated with formation of different skeletal tissues during bone healing

Miller

Gerstenfeld

Morgan

2015

Biomech Model Mechanobiol

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Uncovering the mechanisms of the sensitivity of bone healing to mechanical factors is critical for understanding the basic biology and mechanobiology of the skeleton, as well as for enhancing clinical treatment of bone injuries. This study refined an experimental method of measuring the strain microenvironment at the site of a bone injury during bone healing. This method used a rat model in which a well-controlled bending motion was applied to an osteotomy to induce the formation of pseudarthrosis that is composed of a range of skeletal tissues, including woven bone, cartilage, fibrocartilage, fibrous tissue, and clot tissue. The goal of this study was to identify both the features of the strain microenvironment associated with formation of these different tissues and the expression of proteins frequently implicated in sensing and transducing mechanical cues. By pairing the strain measurements with histological analyses that identified the regions in which each tissue type formed, we found that formation of the different tissue types occurs in distinct strain microenvironments and that the type of tissue formed is correlated most strongly to the local magnitudes of extensional and shear strains. Weaker correlations were found for dilatation. Immunohistochemical analyses of focal adhesion kinase and rho family proteins RhoA and CDC42 revealed differences within the cartilaginous tissues in the calluses from the pseudarthrosis model as compared to fracture calluses undergoing normal endochondral bone repair. These findings suggest the involvement of these proteins in the way by which mechanical stimuli modulate the process of cartilage formation during bone healing.

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Section: Discussioncontrasting

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Mechanical microenvironments and protein expression associated with formation of different skeletal tissues during bone healing

Miller

Gerstenfeld

Morgan

2015

Biomech Model Mechanobiol

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“…Material properties were obtained in a previous study [26] (cf. Table 1) and were assumed as linear elastic and isotropic.…”

Section: Methodsmentioning

confidence: 99%

Numerical Simulation of Callus Healing for Optimization of Fracture Fixation Stiffness

et al. 2014

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The stiffness of fracture fixation devices together with musculoskeletal loading defines the mechanical environment within a long bone fracture, and can be quantified by the interfragmentary movement. In vivo results suggested that this can have acceleratory or inhibitory influences, depending on direction and magnitude of motion, indicating that some complications in fracture treatment could be avoided by optimizing the fixation stiffness. However, general statements are difficult to make due to the limited number of experimental findings. The aim of this study was therefore to numerically investigate healing outcomes under various combinations of shear and axial fixation stiffness, and to detect the optimal configuration. A calibrated and established numerical model was used to predict fracture healing for numerous combinations of axial and shear fixation stiffness under physiological, superimposed, axial compressive and translational shear loading in sheep. Characteristic maps of healing outcome versus fixation stiffness (axial and shear) were created. The results suggest that delayed healing of 3 mm transversal fracture gaps will occur for highly flexible or very rigid axial fixation, which was corroborated by in vivo findings. The optimal fixation stiffness for ovine long bone fractures was predicted to be 1000–2500 N/mm in the axial and >300 N/mm in the shear direction. In summary, an optimized, moderate axial stiffness together with certain shear stiffness enhances fracture healing processes. The negative influence of one improper stiffness can be compensated by adjustment of the stiffness in the other direction.

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“…This enables a direct comparison between different mechanical conditions. Thus, according to experimental data, we identified more cartilage formation under axial compression than under shear loading conditions …”

mentioning

confidence: 65%

“…Tissue composition (a mixture of three tissue types: woven bone, fibrocartilage, and connective tissue), material properties (assumed as linear‐elastic isotropic), and blood supply were assigned to each of the finite elements. For the resulting Young's modulus E j of each element j , a rule of mixtures was used according to Steiner et al:

E_{j} = E_{conn} + c_{cart}^{3.1} (E_{cart} - E_{conn}) + c_{bone}^{4.5} (E_{bone} - E_{conn}),

where E conn , E cart , and E bone are the Young's moduli for connective tissue, cartilage, and bone, respectively (cf. Table ); c cart and c bone are the respective tissue fractions for cartilage and bone within one element.…”

Section: Methodsmentioning

confidence: 99%

Disadvantages of interfragmentary shear on fracture healing—mechanical insights through numerical simulation

Steiner

Claes

Ignatius

et al. 2014

Journal Orthopaedic Research

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The outcome of secondary fracture healing processes is strongly influenced by interfragmentary motion. Shear movement is assumed to be more disadvantageous than axial movement, however, experimental results are contradictory. Numerical fracture healing models allow simulation of the fracture healing process with variation of single input parameters and under comparable, normalized mechanical conditions. Thus, a comparison of the influence of different loading directions on the healing process is possible. In this study we simulated fracture healing under several axial compressive, and translational and torsional shear movement scenarios, and compared their respective healing times. Therefore, we used a calibrated numerical model for fracture healing in sheep. Numerous variations of movement amplitudes and musculoskeletal loads were simulated for the three loading directions. Our results show that isolated axial compression was more beneficial for the fracture healing success than both isolated shearing conditions for load and displacement magnitudes which were identical as well as physiological different, and even for strain-based normalized comparable conditions. Additionally, torsional shear movements had less impeding effects than translational shear movements. Therefore, our findings suggest that osteosynthesis implants can be optimized, in particular, to limit translational interfragmentary shear under musculoskeletal loading. With the use of numerical models, distinct effects of different loading modes on fracture healing can be simulated. [17][18][19] Recently, we developed a numerical fracture healing algorithm, 20-22 which allows us to investigate the influence of single input parameters on the change in IFM and tissue distribution over the healing time. This enables a direct comparison between different mechanical conditions. Thus, according to experimental data, we identified more cartilage formation under axial compression than under shear loading conditions. 22The present study compares healing outcomes of different loading directions (i.e., axial compression, and translational and torsional shear) under normalized mechanical conditions using our calibrated sheep fracture healing algorithm. The aims were to identify adverse conditions and to explain them based on the predicted tissue development over time.From a mechanical point of view, translational shear and axial compressive loading lead to regions of compressive hydrostatic pressure (negative dilatational strain) which stimulate cartilage development, and therefore promote endochondral ossification. 2,[23][24][25] In contrast, torsional shear loading leads only to distortional strains without compressive hydrostatic pressure generation, which suppresses cartilage development.Thus, we hypothesize that differences in healing outcomes are because of differences in cartilage formation resulting from mechanical tissue strain conditions. METHODS Numerical Fracture Healing ModelWe used a numerical fracture healing simulation algorithm that w...

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Prediction of fracture healing under axial loading, shear loading and bending is possible using distortional and dilatational strains as determining mechanical stimuli

Cited by 47 publications

References 57 publications

Mechanical microenvironments and protein expression associated with formation of different skeletal tissues during bone healing

Mechanical microenvironments and protein expression associated with formation of different skeletal tissues during bone healing

Numerical Simulation of Callus Healing for Optimization of Fracture Fixation Stiffness

Disadvantages of interfragmentary shear on fracture healing—mechanical insights through numerical simulation

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